The electric field of a plane electromagnetic wave is given by
`vecE=E_(0)(hatx+haty)sin(kz-omegat)`
Its magnetic field will be given by :

The electric and magnetic field of an electromagnetic wave is

The electric field of a plane electromagnetic wave is given by vec(E)=E_0haticos(kz)cos(omegat) The corresponding magnetic field vec(B) is then given by :

The magnetic field of a plane electromagnetic wave is given by: vec(B)=B_(0)hat(i)-[cos(kz- omegat)]+B_(1)hat(j)cos(kz+omegat) where B_(0)=3xx10^(-5)T and B_(1)=2xx10^(-6)T . The rms value of the force experienced by a stationary charge Q=10^(-4)C at z=0 is close to:

The magnetic field of a plane electromagnetic wave is given by: vec(B)=B_(0)hat(i)[cos(kz- omegat)]+B_(1)hat(j)cos(kz+omegat) where B_(0)=3xx10^(-5)T and B_(1)=2xx10^(-6)T . The rms value of the force experienced by a stationary charge Q=10^(-4)C at z=0 is close to:

The magnetic field in a plane electromagnetic wave is given by vecB=2×10^-7 [sin(0.5×10^3x+1.5×10^(11)t)hatj] . The electric field is given by (where B is in T , x is in m and t in s)

The electric field of an electromagnetic wave travelling through vacuum is given by the equation E = E_(0) "sin"(kx - omegat) The quantity that is independent of wavelength is

Magnetic field in a plane electromagnetic wave is given by bar(B) = B_(0)"sin"(kx + omegat)hat(j)T Expression for corresponding electric field will be

Magnetic field in a plane electromagnetic wave is given by bar(B) = B_(0)"sin"(kx + omegat)hat(j)T Expression for corresponding electric field will be

Electric field of an electromagnetic wave vecE = E_0 cos (omegat-kx)hatj . The equation of corresponding magnetic field at t=0 should be

The electric field of a plane electromagnetic wave propagating along the x direction in vacuum is vecE = E_0 hatj cos (omegat - kx) . The magnetic field vecB , at the moment t=0 is :